Dynamic concatenation leads to anomalous transport of ring DNA in concentrated solutions.

Abstract

Circular DNA polymers have been widely studied due to their biological relevance as well as the unique anomalous transport properties they exhibit in concentrated solutions and blends with linear DNA. In cells, topoisomerase II relaxes torsional strain in circular DNA by cutting and then reconnecting one of the strands of the double-stranded polymer, enabling replication, transcription, and repair. When topoisomerase II acts on nicked circular DNA at high concentration, the relaxed rings can concatenate, forming Olympic ring structures reminiscent of kinetoplasts. The rate of topoisomerase activity as well as the concentration and size of the DNA can tune the nonequilibrium dynamics and conformations of the concatemers. Here, we visualize the fluorescent-labeled DNA rings comprising the concatemers and use particle tracking and differential dynamic microscopy to characterize the dynamics and time-varying size and shape of the actively linking and unlinking molecules. Beyond the insight our work provides to biological processes mediated by active restructuring of DNA, the complex fluids we engineer and study may have applications in the design of biocompatible active materials for cellular repair, toxin filtration and drug delivery.